Record controlled printing means



1954 A. B. CROWELL RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 13, 1947 16 Sheets-Sheet l INVENTOR ARNOLD B. CROWELL J3 ATTORNEY Feb. 16, 1954 A. B. CROWELL RECORD CONTROLLED PRINTING MEANS Original Filed Aug. '13, 1947 16 Sheets-Sheet 2 INVENTOR ARNOLD B. CROWELL Feb. 16, 1954 A. B. CROWELL 2,669,178

' RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 15, 1947 16 Sheets-Sheet} INVENTOR ARNOLD B. CROWELL BY ,J 7 14.

AT ORNEY Fb; 16, 1954 'A. B. CROWELL 7 2,669,178 I RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 15, 1947 16 Sheets-Sheet 4 INVENTOR o ARNOLD B. CROWELL ATTORNEY 1954 A. B. CROWELL RECORD CONTROLLED PRINTING MEANS l6 She'ets-Sheet 5 Original Filed Aug. 15, 1947 VZE on Fun 96 20 2958 T .m. uzzzza MN If? E5 2965 920 N\ 5 Z ZIIIL wwwwwmwwuwmm mmwww CROWELL c RNEY ATT 1954 AB. CROWELL 2,669,178

RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 15, 1947 f w 16 Sheets-Sheet 6 6O PRINTING COLUMNS ON CARD '=1 INVENTOR ARNOLD B- CROWELL BY 5 fan,- (2 4 7 ATT RNEY Feb. 16, 1954 B, wE-LL 2,669,178

RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 13, 1947 16 Sheets-Sheet 7 II/I ATT RNEY 9.. ENT

'ARNOL B C WELL Feb. 16, 1954 A. B. CROWELL 2,669,178

RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 13, 1947 16 Sheets-Sheet 8 216 I g i \3 5l6 m tv I, IG 11- FIG. 12.

. I INVENTOR ARNOLD B. CROWELL ATT RNEY 1954 A. B. CROWELL RECORD CONTROLLED PRINTING MEANS l6 Sheets-Sheet 9 Original Filed Aug. 13, 1947 30L 26L 3-0L INVENTOR ARNOLD B. CROWELL y AT RNEY Feb. 16, I951 A. B. CROWELL RECORD CONTROLLED PRINTING MEANS 16 Sheets-Sheet 11 Original Filed Aug. 15, 1947 INVENTOR ARNOLD B. CROWELL Feb. 16, 1954 Original Filed Aug. 13, 1947 A. B. CROWELL 2,669,178

RECORD CONTROLLED PRINTING MEANS l6 Sheets-Sheet l2 DIIJTH D ELUST J Q I-gN SM 113 M I] D DD 46| l/ 425 HI M HI I 353 431 f l .446 E? a". LZJ I" g? I Z O 450 4 7 INVENTOR ARNOLD B. CROWELL ATT RNEY BY X Feb. 16, 1954 A, B. CROWELL 2,669,178

RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 13, 1947 16 Sheets-Sheet 13 PERMUTATION BAK 1 2 3' -4 SET PINS HOLES IHIIIIIIHIIHHH HHHHHHHHHIIHHHHHIHHIIIHHIIHIIII HHHHIHIHHHHHHHIIII'IIIIHIIHIIIIIIHIH Hll HIIIIIIIIH IHI HHHHHIH I ARNOLD B. CROWELL FIG. 24 BY w ATT N EY Feb. 16, 1954 A. B. CROWELL RECORD CONTROLLED PRINTING MEANS l6 Sheets-Sheet 14 Original Filed Aug.- 13, 1947 omz m m2 vmz m m2 wmz 26 wzaomwm .25 185% $2135 25 025% z: H6502! EE 5292 2% E40 14$ 13 Gm ARNOLD B. CROWELL Feb. 16, 1954 A. B. CROWELL 2,669,178

RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 15, 1947 16 Sheets-Sheet l5 sw1 f 62| 62o MOTOR RELAW-i STAR T I LS w R4a Sam RIb CFCMl HC 23"" C8 5 M760 A B324 R'ZEJ A CLC 2 2 ARNOLD B. CROWELL 2661. BY%

ATT RNE Feb. 16, 1954 A. B. CROWELL 2,669,178

RECORD CONTROLLED PRINTING MEANS Original Filed Aug. 13, 1947 16 Sheets-Sheet 16 l lie 4d F 1 t {.111 4 2:; MlOO E 4 RIF CB6 B 55 R25b Rzs gj 3 R24 1 l GANG PRINT CONTROL SW. 7

M320 AF L...! 8 25 I 629 m 6 b E23 READ CONTROL SWITCH RsF 'u-i/ 657 INVENTOR ARNOLD B. CROWELL Fla-26B. I l

Patented Feb. 16, 1954- RECORD CONTROLLED PRINTING MEANS Arnold B. Crowell, Endicott, N. Y., assignor to International Business Machines Corporation, New York, N. Y., a corporation of New York Original application August 13, 1947, Serial No. 768,373. Divided and this application August 12, 1949, Serial No. 109,995

4 Claims. (01. 101-93) This invention relates to a multiple-column automatic recording machine and its principal object is to provide a more efficient machine of this type.

The present application is a division of my pending application, Serial No. 768,373, filed August 13, 1947, now U. S. Patent No. 2,598,511.

A particular object of the invention is to provide a multiple-column printing mechanism which can be set up automatically to print the same data repeatedly, until the set up is changed under signal control.

Another object is to provide a multiple-column printer having an improved electrical arrangement for suppressing the printing of zeros in certain columns, depending upon the position of the first significant digit of a number.

In accordance with another feature of the invention the machine can be made to print asterisks in place of zeros to the left of the first significant digit of a number, or to extend the printing of asterisks still further to the left, for

any desired number of columns.

Another object is to provide a record-controlled multiple-column printing mechanism with improved means to suppress printing on certain cycles, under control of the record.

Still another object is to provide 'a recordcontrolled multiple-column printing mechanism with means to store data from a record in set-up means which control repeated printing of the same data on successive records, until a record appears which signals the discharge of the first data and the storing of new data.

Other objects of the invention will be pointed out in the following description and claims and illustrated in the accompanying drawings, which disclose, by way of example, the principle of the invention and the best mode, which has been contemplated, of applying that principle.

In the drawings:

Fig. 1 is a side elevation of an interpreter embodying the invention.

Fig. 2 is a vertical section of the card feed unit, looking in the opposite direction to Fig. 1.

Fig. 3 is a detail view of a part of the line adjusting mechanism.

Fig. 4 is a side elevation of one part of the printing drum operating mechanism.

Fig. 5 is a side elevation of another part of the I printing drum operating mechanism.

Fig. 61s a plan view of a portion of the card feed unit, showing the printing drum end.

Fig. '7 is a timing chart of the printing drum.

Fig. 8 is a plan view of the printing unit.

Fig. 9 is a side elevation of the printing unit, looking in the direction opposite to Fig. 1.

Fig. 10 is a vertical section substantially on the line Iii-l0 of Fig. 8.

Figs. 11 and 12 are detail views of the hammer hook bail mechanism, in two different positions.

Fig. 13 is a vertical section substantially on the line l3-I3 of Fig. 8, with parts omitted.

Figs. 14, 15 and 16 are diagrammatic views showing the hammer firing operation.

Fig. 17 is a vertical section of a portion of the printing unit, in substantially the same plane as Fig. 10, but showing the pin set up mechanism.

Fig. 18 is a section on the line I8l 8 of Fig. 17.

Fig. 19 is a detail view of a portion of the mechanism shown in Fig. 1'7, but at a different time in the cycle.

Fig. 20 is a portion of a tabulating card illustrating the punching and interpretation.

Fig. 21 is a detail view of the interposer frame of the pin set up mechanism and its operating means.

Fig. 22 is a detail view of a portion of the vertically moving interposer frame supporting means.

Fig. 23 is a detail view of the set pin restoring means.

Fig. 24 is a diagram of the permutation bar and set pins.

Fig. 25 is an electrical and mechanical timing chart of the machine.

Fig. 26 is a wiring diagram.

Theinvention is applicable to various kinds of automatic recording machines, one of which is the tabulating machine such as shown in Paris Patent No. 2,398,036, but I have chosen for illustration of the invention an interpreter, because of some features concerned particularly with interpreters.

Fig. 1 of the drawing shows the general arrangement of an interpreter embodying the principles of the invention. It comprises a card feed unit A at the right or front end of the machine and a printing unit B at the left or rear end. The functions of the card feed unit are to feed cards one at a time to a control station, where their control designations are analyzed; then to a reading station, where the data stored in them is read; then to a printing station, where the data is interpreted on the cards by the printing unit; and then to a stacker. The function of the printing unit is to store the data read from the cards and to print the data on the cards as they are presented in succession at the printing station.

The cards for which the illustrative machine is designed are the standard 80 column International tabulating cards, one of which is partially shown in Fig. 20. These cards are divided into 80 vertical columns (see the small column numbers at the bottom of the card), in which data is stored by punching holes in one or more of 12 horizontal rows or index point positions. These index point positions are identified, be ginning with the top, as R, X, 0, l, 2, 3, 4, 5, 6, 7, 8, and 9. The card shown in Fig. has stored in it, by perforations in columns 1 to 22, John Smith 115 Elm St. Fig. 24 shows the perforation code under the heading Holes. Fig. 20 shows the card after this information stored by means of punched holes has been interpreted by the machine disclosed in the drawing. In this case the line of interpretation is the line just below the uppermost, or R, index point pos-i tion. As will be seen later, the interpretation may be placed in any index point position except the 9 position, or on a line just above any one of the index point positions. The character spacing of the interpretation is somewhat wider than the column spacing of the punched record.

The card feed unit A stack of cards It is placed in a hopper ii at the right end of the machine shown in Fig. 1, face down and with the 9 row forward, that is to the left in Fig. 1. Fig. 2 shows the card feed mechanism in vertical section as seen from the opposite side from Fig. 1. At the bottom of the card hopper is a picker mechanism, which comprises a reciprocating member 12 provided with a knife 53 projecting above the top surface of the member 2 for slightly less than the thickness of one card. The picker mechanism is reciprocated by rocker arms M fixed to a rock shaft it, which has fixed at its remote end in Fig. 2 a rocking lever l6 urged in one direction by a spring I! and moved counterclockwise once each machine cycle by a vertically travelling pitman l8 articulated to its left end. The slide has a cam follower roller I9 bearing upon a cam fixed to the end of the main card feed shaft 2!. This shaft is driven by a bevel gear 22 meshing with a bevel gear 23 fixed to a gear 24 meshing with a gear 25. The latter gear is retatably mounted on a shaft 26 and has fixed to its hub a clutch arm 2'! on the end of which is pivoted a clutch dog .28. An outwardly directed tail 29 of the dog 28 and a tip of the clutch arm 27 directly behind it are normally latched by a hook 3!) controlled by the card feed clutch magnet CFCM. When this magnet is energized the hook releases the clutch dog and the clutch arm and the dog is pulled by a spring 3! into engagement with a notched disc 32 fixed to a gear 33. The gear 33 is driven through gears .34, 35, and 3G, by a gear 3! on a shaft 38. The shaft 38 has keyed to it a pulley 39 driven through a belt 39' by a motor, not shown in Fig. l. The clutch arm 27 will make one revolution and will then be latched up, by the hook 3B ifthe card feed clutch magnet has not been energized again. One revolution of the clutch arm causes one cycle of operation of the card feed nit- Once in each cycle the picker knife l3 moves back to take hold of the rear edge of the lowest card in the stack and is then moved forward by the spring I! to feed the card out of the bottom of thehopper into a pair of feed rolls 40, 4|. There are three other sets of feed rolls in the card feed unit: 42, 43; it, 45; 46, 47. The feed rolls 49, 4S and d4, 45 are purely conveying rolls, while the lower one of each pair of feed rolls @2, 43 and 36, 4"! is called a contact roll and has an electrical function in addition to its conveying function. The feed rolls feed the card between card guides 48. The contact rolls 43 and M have a metallic surface on which bear brushes 5t and 35!, through which they are electrically connected with one side of the line. On the upper side of each of the contact rolls 43 and il bears a set .of analyzing brushes 52 and 53. There are 88 brushes in each set, one for each column of the card, and they are mounted in electrical isolation on insulating bars 54 and 55. iJhe brushes 53 are called reading brushes, because they read the data stored by the punched holes in the card and transmit it to the storage device of the printing mechanism. The brushes 52 are called control brushes, because they are concerned with controlling the operations of the machine.

The lower feed rolls 4i and 45 are driven from the shaft 21 :by pairs of bevel gears '56 and drive the contact rolls 43 and 47 through gears 51.

The printing drum 'From the feed rolls 46, 41 the cards pass through the last card guides 53 to the printing drum 6B. The printing drum comprises two independently operable platen members BI and 62. The platen member ti is shown in the position it assumes for holding the card at the printing station, opposite a row of type members 63, while the platen member 62 is shown in card receiving position. When the card held by the platen member H has been printed upon, this platen member advances counterclockwise to the position in which platen 52 is shown in Fig, 2, leaving its card in a stacker E4 in passing. At the same time, the platen member 62 advances from the card receiving position to the printing station. ,In the next machine cycle a card held by platen member .82 will be printed upon and then conveyed to the stacker 64, while the platen member El will receive the following card from the feed rolls 46, ii.

The two platen members are generally similar in construction, but have slight differences, due to the fact that one is nested inside the other. Fig. 1- shows the platen member 52 and its actuating mechanism alone, in card receiving posi tion, while Fig. 5 shows the platen member 6i and its actuating mechanism alone, in card printing position. Referring first to Fig. i, the platen member comprises a cylindrical platen 53 which is supported by two side arms 6? and 58 on the shaft t5 (see also Fig. 6). The hubs of these side arms are fixed to the shaft by set screws 89. Atthe front edge of the platen 35 is a card clamp comprising a shaft it and clamp fingers '52. The shaft ii! is rockably mounted in flanges it of the platen and can rock sufliciently to withdraw the clamp fingers 12 from the platen surface to accept a card. Each one of the clamp fingers has associated with it a spring 74, one end of which is hooked over a pin 15 on the hub of the clamp finger, while the other is anchored on a shaft 716 which extends for the length of the'platen member. These springs normally hold the card clamp shut. The shaft iii has fixed to it 9. lug l? which coacts with a stationary cam it. This cam 58 has a hump 19 which rocks the clamp open at the card receiving station and another hump 83 which rocks it open as the card is delivered to the stacker. At all other times the clamp is closed. "Two-clips 8| serve as card stops when the platen member is in card receiving position. A 111g 92 with a v notch 83 coacts with a spring detent 84 to hold the platen member in card receiving position.

The shaft 65 has pinned to it a hub 85 (Fig. 6) with a single-notched clutch flange B. Beside the flange 86 is a hub 87 revolvably mounted on the shaft 65 and held inplace by a spacer 88. The hub 81 has a clutch arm 89 on which is pivotally mounted a clutch dog 90 cooperating with the clutch flange 86 and pressed thereagainst by a"'spring 9!. The hub also has'a setof gear teeth 92 meshing with the'teeth of a large sector 93 revolvably mounted on a shaft 95. The'larg'e sector is connected by a spring 95 hooked over its pin 96 'to'a pin 91 on a driving arm I00 rotatably mounted on shaft 94'. The'pin 91 extends through an opening" IOI in sector 93. The large sector 93 also'has a bearing'stud I02 projecting through a slot I03 in driving arm I00, on which is revolvably mounted a cam' I05. Against this cam bears aroller I09 mounted on a stud I0! on the driving arm I00. The large sector 93 and the driving arm I00 normally have the relative position shown in Fig. 4, but by rotating the cam I05 the large sectorcan be made to move to'the right in relation to the driving arm. The hubof the cam I05 has a set of gear teeth I08 meshing with teeth I00 of a small sector III! also revolvably mounted on shaft 94. The small 'sector'has an arm I I5 secured to it by screws I I6 and carrying a roller III-atits". upper end whichrests against a stop H8 at the particular-time in the machine cycle illustrated in Fig. 4. The small sector is urged toward the right, in relation to the driving arm, by a spring II9 hooked over its pin I and a pin I2I on the driving arm I09. In order to move to the right the sector III] would have to rotate the gear I08, because the supporting stud I92 of this'gear is fixed to the large sector 93, which has a definiterelation to the driving arm I00 established by the spring 95 and cam I95. 'The spring 55 is strong enough to prevent rotation of gear I08 by spring H9. The driving arm I00 has revolvably mounted on it a roller I2 3 riding on a cam I25. An extension I26 of the driving arm I80 carries a roller IZ'I bearing upon a complementary cam I28. Both of these cams are pinned to a shaft I30. A gear I3! (Fig. 5) is also pinnedat its hub to the shaft I30 and meshes with a gear I32 on the shaft I33 of the lower feed roll 5. The ratio of the gears I3-I and I32 is such that the cam shaft I90 turns one revolution in two machine cycles.

In operative relation to the roller IITis a cam I 35 pinned to a shaft I35. 'This shaft has secured to it a gear I3'I (Fig. 3) meshing with a gear I38 fixed to a shaft I39. The shaft I39 has a hand knob I49 bearing graduations, which move in relation to an index mark IM to indicate the line of the card on which the interpretation will be printed. The movement of the camI-35 is limitedby anarm M2 on gear I37, in the path of which are two stops I 43. The manner in which the printing line is determined by this mechanism will be described presently.

The alternate platen mechanism 'IiI differs from the one first described in a number of respects, which will now be pointed out, with reference to Figs. 2, 5, and 6. A cylindrical platen 69 has two supporting arms 6? and 08 which it ismoi1'rit"ed on the'sha'ft65'; these'arms lying outside of the'arrns 61 and'68 of the platen member 62- and being revolvably mountedbn the shaft'65. Theca'rd clamp 10312", 14","15'; "I'I'; is-: substantially identical to that of the platen mechanism 62, the-operating lug TI" being controlled bythe same stationary cam I8. The arm 61 has fixed to it a flange'l45 on a tube I46 revolvably mounted on shaft 65-, which extends out to a" terminal single-notch clutch flange Revolvably mounted on the shaft 65 beside the clutch flange '86" is' a hub 81 having a clutch arm 89' pivotally supportin a spring operated clutch dog 90": On the hub 8'! is a gear 92' meshing with a large sector '93; The'operating mechanism for this platen member is the same as the one first described and is identified in the drawing by similar reference numerals with prime marks. The'only diiference is that the main driving cam" I25 and complementary cam I20'--are' angularlydis'placed, in relation to the corresponding cams I25 and I28 by The line adjusting cam I35 is mounted on shaft I39 at the same angle ascam I35.

The-operation of the printing drum will now bedes-cribedfby' referring'to'the platen member 62 and its operatingmechanismfwhich are shown I in 'Figf'4' at 32lL'Z5"'inachine time, and to the card feed'timin'g'chart; Fig-. 7. The cam follower 12d is atthel'cw part 'of'the' cam I25 at this time. Theplaten'member stands in card receiving position and the card clamp is open.

: The lug 17 is just on the edge of the hump I9 of cam' TB, so that the slightest forward movement of the platen m'embefwill cause it to drop off the stationary camand' clamp" thlebottom edge of "thecai'd. The -platen*memberTiZ is detented in card receiving position by detent spring 84 engaging a notch"93." The knob I40 is set to print on the lowest printin'g'line, midway between the 8'and'9 indexpoint positions. j Whenthe cam' I25-turns counterclockwise the driving arm'l00 swings to the right. The roller I06 pushing against the cam I 05 moves the large sector 93 to the right and rotates the platen member 02in' counterclockwisedirection; The card blamp engages 'the card as soon as this movementbegins' and as the cam I25 turns to 72" of the 'machinecycle; the" card 'is conveyed up to the printing-station, (seecurve I50, Fig. 7) where it is held bottom edge up, with the lowest printing'linin position opposite" the line of type 03. The small sector IIITfollowsthe movement'of the'driving arm I09 and large sector 93, the roller I I1 striking the surface of cam I35 just at 712. 'During'the next'part of the machine .cycle, until 308;56,t'here'is no'further movement of the platen member 62, while the cam follower is travellingon' the concentric portion of the cam I25. The'printing takes'place during this time, the type beingposit'ioned upside down, because of the inverted position of the card. The opera tiori so far'described' occupies almost one machinecycle. p

Further" rotation or the cam I25 swings the driving arm I00 emerge sector 93further to I the rightand drives the platen member 92 on in counterclockwise direction from the printing station." The platen member passes through'the highest point" of its revolution at 334.63", stacks the" cardat 57.27, and arrives at the card receiving station at 185.04", the follower I 24 rolling over the highest point of cam I25 at this time. The platen memberisglatched up by the detent 04 and the dog 90fid1 es'bacli over the clutch disc as; dropping'into the'notch or the disc again after compu ing a clockwisrevolution.

*Part of" tlie 'motion ofthe platen member 62' after 308.56 is due to the action of the cam I05. As soonas the further motion of the large sector 93 begins the cam I05 begins to revolve clockwise, because the arm I I5 is stopped by the line setting cam I35 and as the shaft of the gear I08 goes to the right the gear rolls on the small sector III], turning cam 105.. This drives the shaft I02 ofthe cam I05 away from the center of roller I06 and has the efiect of making the large sector 93 move forward more rapidly than the driving arm I 00. The accelerated movement of the large sector ends when the rol1er- I'06 moves ontothe high concentric part of the cam I05; from then on the large sector and-the drivingarm'move at the same .rate. a In the diagram,-=Fig;= 'l, the vertical distance represents circumferential trav e1 of the platenmember, the direction beingflre= versed at. 334.63 the highest pointxin the path of the platenmember. I Adjusting the riming If the cam I35,is, adjusted .to the positionifor printing above the R row, the roller. I lrhcomes into contact, early in the. rightward movement of the-driving arm I-and the accelerated-movement of the large sector-93 beginsbeforethe card reaches the printingstation, as shown-by the curve I Hi. Thus the platen member ad vances a greater distance. before the roller.l24 comes .onto. the concentric portion ,of. cam 125, which occurs at the time-the roller,I06 rides onto the concentric portionof. cam-105;.The card is held inposition for printingongthe line above the RKrow, duringthe =dwellin-cam Itwill be seen that the movement of thelarge sector is ,.derived vfromthecams 112-5; :and I and its total movement is thesame inall cases. The only, thing.that changes; is: the timing of the accelerated ,motiomcaused by. the cam. I05, which varies. independence upon the-position of the line adjusting1cam..l35. H

The movement of the. platen member 6| :from the card receivingstation begins; at 321.75", one cycle later than .the:movement:0f .the -..pla.ten' member;62- from the cardreceiving; and at. the time the latter platen member ison its way from the'printing station to the stacken- Themovev. ment of the platen member 6| is shownl byathe These curves; start. at a lower level. than the curve: I 50, to represent the fact that the platen -member'62 has advanced some distance out of the-,printing'position be.- fore .the platen member 6 ceiving station. 3 i

In its travel with the platen :sector the. card is guided by cylindrical guides I52.and153;which are separated at, the printing position to. en.- able the type toprint upon the; card.-v .-Leaving the guide I53, the..card-passes outside of two narrow card guides I54 and I55 and-.behinda displaceable stacker. plate I56, w.-hi ch1rides upon rollers 151 in grooves I58. of ,=-a stacker chuteJ-BB.

As acardstrikes the bottomofthe stackerlchute cam 118. As the card, stack builds .up; .in. the.

stacker the plate-I56 travels up thestacker chute to accommodate the. growth of the stack.

Certain icontacts jto be referred, -to later on as the CB contacts,aredrivenwhenever. the card feed is running. The cams, which operate I. leaves-the card, re-

these contacts are shown at I60 and are mounted on a shaft I6I driven through gears I62 by a gear on the shaft of the lower feed roll 4!. The latter gear is of the same size as the gear 5'! on this shaft and for this reason cannot be seen in Fig. 1. The timing of the CB contacts is shown in Fig. 25. Another cam contact, CRI, is operated by a cam I63 on continuously running shaft I64 of gear 34, which rotates once each cycle.

v, The printing fine'chanis'ht I .Therinting mechanism is, in, general, similar to the oneshown in .thelParis Patent: 2398,0136. The type members 63. are-mounted yon a type carriage 200 (Figs. 1,8, and.9) which reciprocates on a line parallel to the axis of the'printing drum 60... The carriage moves .the type members-:past a set of printing hammers 20L The printing mechanism shown is designedrto print 60 characters on aline; accordingly, thereare 60 printing hammers. The typemembers are mounted on the type carriageso as .to be movable transversely to the carriage-to execute individual printing strokes. In=theillustrative machine there are. :103 type members. These .include two .complete sets of type. members and part of, a third set. Eachset is composed of the26 characters of the alphabet, the 10 digits, and seven .specialcharacters and punctuation marks. The two sets are identical in. sequence and compositionand the thirdv set, as far as it goes, is identical to the other two.

The length .of thestroke of "the type carriage is somewhat greater than the movement required to' present to any-given column all. of the type members of one complete set. During a printing-stroke .of. the type carriage there willxbe one instant. when the'type member bearing the, character :to be printed in a particular column is exactly in front ofthat column.- For example, the fourth typezmemberfrom the left endof the type bar, whichbears the type R, Willbe exactly opposite printing column 60 of theicardnear the'end of the'rightward' stroke of the carriage. If anR is to be printed in column 60 a set up mechanism, to be describedpresently, will have a particular setting for column 60. representing the letter R and will release the printing ham mer pertaining to column 60 atthe correct time to strike thetype member bearing the letterR, so that the latter will strike thecard exactly in column 60. 1

The details of the type carriage are shown particularly in Fig. 10. 'It comprises a base member- 202 and achannel shaped type'barzilti composed-of a bottom member- 204 and front and rear. plates. 205 and 205. Ball bearings 20? between races 208 on the base member 202 and races-209 -ontwo stationary members 2M and 2H mountthe carriage. for reciprocating motion. The typegcarriage' isstabilized in its movement by a-rack and gear arrangement 2I2. The-front plate 205' and rear plate 206 areuslottedx toproa vide guide ways for the type members 63. Inorder to permit high speed printing the type members shown are composed ofbody' portions 2E5 guided in the slots of the plates 285 and 206, and pivoted headportions 216 mounted on they body portions byyerticalpivots 2|]. Each head. portionis normally held by arelated spring 2 it in alignment. with the. body. portion andthis spring also holds the type member against a. rest- ZIQ. Each type memberexecutesa printing movement when. struck byra hammer 201-, striking through 

